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The Production of Fissile Materials for Nuclear Weapons and Nuclear Power

The Production of Fissile Materials for Nuclear Weapons and Nuclear Power. Adam Bernstein Physics and Advanced Technology Directorate Lawrence Livermore National Laboratory June 23 2010. Definition of the Nuclear Fuel Cycle.

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The Production of Fissile Materials for Nuclear Weapons and Nuclear Power

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  1. The Production of Fissile Materials for Nuclear Weapons and Nuclear Power Adam Bernstein Physics and Advanced Technology Directorate Lawrence Livermore National Laboratory June 23 2010

  2. Definition of the Nuclear Fuel Cycle • The set of processes to obtain, refine, and exploit nuclear material for a specific purpose • There are several different types and subcategories • power • weapons • naval reactor fuel • radioisotope production • research • Cycles also vary: • in degree of opportunity to obtain directly weapons-usable material • In degree of difficulty in safeguarding * New cycle are now being contemplated in the US and world-wide – their proliferation consequencesmust be carefully considered Example: The Open nuclear fuel cycle for power production in the United States

  3. Civil and military fuel cyclesoverlap Weapon Assembly Natural Uranium Enriched Uranium “Open” Cycle “Closed” Cycle Plutonium To Repository This recognition is the basis for the nuclear nonproliferation treaty

  4. Why is there overlap? because enormous amounts of energy can be extracted from small amounts of fissile material – slowly or quickly Fission of uranium and plutonium can release many orders of magnitude more energy per unit of mass than ‘chemical’ combustion of sources like coal Three tons (3000 kg) of fissile material in the ~10 cubic meter San Onofre Unit 2 reactor core power a few million homes in O.C. for a year • The energy density of Plutonium: • about 1014 Joules/Kg • The energy density of Coal: • about 107 Joules/Kg Fissile material produces 10,000,000 times energy per unit mass than coal Some isotopes of plutonium and uranium also make great explosives, requiring little mass per unit of destructive power IAEA Standard: 8 kg of Plutonium or 25 kg of High Enriched Uranium suffice to make a Hiroshima size (or greater yield) nuclear weapon

  5. What is fissile material ? • Material that can be made to undergo a nuclear chain reaction, consisting of successive fissions, with high energy release • Controlled release = Reactor • Uncontrolled release = Explosive • Also called “Special Nuclear Material”, “Special Fissionable Material” • For practical purposes, there are two materials for weapons production • Highly Enriched Uranium and Plutonium • And three ways to acquire them • Highly Enriched Uranium may be obtained via Enrichment • Plutonium may be obtained via Reprocessing • Either may be obtained via theft or purchase • Other possibilities for weapons manufacture exist • 233U; neptunium; americium • There are far less of these materials in the world

  6. Acquiring fissile material is the most difficult step in making a nuclear weapon • Dominates the time to achieve a nuclear weapons capability • Dominates the cost of a nuclear weapons program • Enrichment (Isotope separation) of uranium and Reprocessing for plutonium separation from spent fuelare particularly difficult • Also difficult: • making gaseous uranium to feed enrichment • producing heavy water or highly pure graphite for reactors that use these moderating materials • building a nuclear reactor These technical obstacles can drive would-be proliferators, especially subnational groups, towards theft, collusion, bribery and other non-technical approaches, to obtain materials and/or technologies

  7. n n n n Nuclear Fission: one neutrons in, a few neutrons out, plus energy 36 Kr90 ,… fission daughters carry away about 90% of the ~200 MeV of energy released per fission 56 Ba143,… daughters themselves decay:emitting delayed neutronsin ms to sec 92U235 A neutron of any energy can cause fission but ‘slow’/’thermal’ neutrons (0.025 eV)are much more likely to fission 235U This ‘fissile’ property of 235U (and 239Pu) is what allows the chain reactions that enable both bombs and reactors 2-3 ‘prompt’ (in a few ns) ‘fast’ (a few MeV) neutrons are emitted by fission not shown: 8-10 gamma-rays (~1 MeV each) also emitted by fission – very useful for detectionbut don’t affect chain reactions in bombs andreactors

  8. With enough fissile mass and density, controlled or runaway nuclear chain reactions can occur A system that sustains a controlled chain reaction is called “critical” Reactor cores are critical – Delayed neutrons control criticality in reactors A system that sustains a runaway chain reaction (for several hundred billionths of a second) is called “supercritical” Bombs are supercritical System is supercriticaluntil it blows itself apart

  9. Vocabulary interlude - fissile versus fissionable versus fertile • Fissile materials – can be fissioned by neutrons of any energy, including zero kinetic energy, capable of sustaining a chain reaction235U,239Pu+ 241Pu • Fissionable materials – can be fissioned only by neutrons above an ~ 1-2 MeV threshold – cannot alone sustain a chain reaction238U, 232Th • Fertile materials – capable of absorbing neutrons to create or ‘breed’ fissile material (more about this in a few moments..)238U, 232Th The Ford Pinto The Ford Volvo ?

  10. Uranium provides fuel for power reactors, can be used to make a nuclear weapon, and is the source of all plutonium U-235 Atom (Fissile) U-238 Atom (Fissionable) Low enriched uranium (LEU) Between 0.7% and 20% U-235 Natural uranium 99.3% U-238 and 0.7% U-235 Highly enriched uranium (HEU) above 20% U-235 (IAEA) Weapons-Grade uranium (WGU) above 90% U-235 (IAEA) Used in power reactors Best for breeding Plutonium Used to make weapons • Uranium enrichment is one of two main paths to a nuclear weapon • Fortunately, it is fairly difficult - chemically identical atoms of slightly different mass have to be separated

  11. Four methods of uranium enrichment have been used on a large scale • Gas Centrifuge: spin uranium hexafluoride gas • High capital cost • Low energy consumption • UK, Netherlands, Germany, Russia, China, Japan, Pakistan, Iraq, Brazil, Iran, Libya • Gaseous Diffusion: force UF6 gas through a membrane • Lower capital cost • High energy consumption • US, Russia, France • Large size • Electromagnetic Isotope Separation (EMIS): accelerate uranium atoms in a magnetic field • Very high energy consumption • Early US, Iraq • Aerodynamic/Jet Nozzle: stationary wall centrifuge • High capital cost • High energy consumption • South Africa Gas Centrifuge Cascade Gaseous Diffusion Unit Calutron Track

  12. Gas centrifuge technology is particularly sensitive • Gas centrifuge plants to produce HEU for weapons have no unique signatures • Modest size • Low energy consumption • Gas centrifuge plants can be easily reconfigured to adjust the enrichment level • Gas centrifuge technology has spread all over the world • A.Q. Khan the most visible distributor • Many countries have the capability to produce gas centrifuge equipment • Key components and manufacturing equipment are export controlled Centrifuge Diagram

  13. Other uses of enriched uranium www.euronuclear.org Problem: globally dispersed SNM, various levels of protection US/IAEA/European/Russian response: Fuel exchange and core retrofitprograms Research reactors LEU and HEU fuel ~280 operational out of 680 built worldwide • Naval reactors • HEU fuel allows • infrequent refueling • rapid power draw • compact size • Problems: • physical protection of cores • treaty accountability • (one) obstacle to a ban on HEU • core disposal

  14. The HEU Purchase Agreement The U.S. has agreed to purchase 500 metric tons of HEU from dismantled Russian nuclear weapons, in the form of 15,000 metrics tons of LEU, for use as reactor fuel for U.S. commercial power reactors. Dismantleweapon heat metal parts in oxygen furnace to make HEU oxide Convert oxide to uranum hexafluoride (UF6) gas usec.com Mix 95% 235UF6 with 1.5% 235UF6 in a ‘Tee’ output = 5% 235UF6 LEU Blend-Down Monitoring System Effect on fuel supply – moderately disruptive Operates all ~104 US reactors for over 2 yearsEffect on HEU stocks and nonproliferation regime – highly beneficial LEU fuel used in U.S. reactors

  15. Inside a typical uranium fueled reactor core ~1 cm3 EnrichedUO2 fuel pellets Hundreds of pellets In a fuel rod 2-3 meters tall Dozens of fuel rods Per assembly 2-3 meters tall ~0.25 m wide 3 meters tall 2 meters wide A few hundred fuel assemblies per core

  16. Plutonium alchemy occurs in reactor cores Alchemy: Plutonium is produced in nuclear reactors by bombarding “fertile” U-238 with neutrons Every reactor in the world produces some plutonium A typical power reactor produces about 300 kg per year 232Th  233U is an alternative fissile material production mechanismbeing considered by some countries

  17. Reactors sustain their reactions in different ways or: Why enrichment is not always necessary Slow neutrons (2200 meters/second) are much more likely to cause fission in 235U than fast neutrons But fissile materials produce fast neutrons Most reactors use water as a ‘moderator’ to slow down neutrons The water reduces the speed of fission-generated neutrons, increases the chance of fission and ensures that criticality is maintained The problem with water: water also absorbs neutrons before they have a chance to cause fission Result: natural uranium doesn’t have enough 235U density to sustain a chain reaction when surrounded by water Water moderated reactors need 235U enriched fuel Graphite and Heavy Water don’t slow down neutrons, as well as Light Water, but they absorb far fewer neutrons Graphite and Heavy Water moderated reactors can use natural uranium – these moderating materialsare therefore proliferation sensitive

  18. All reactors produce some plutonium, some are best for weapons plutonium • natural uranium fueled reactors have some advantages for weapons Pu production • The most efficient way to produce Pu • Don’t need to buy or make enriched uranium • Reactor must use either Heavy Water or Reactor grade graphite – both are difficult to obtain • A 40-MW natural uranium fueled reactor will produce about 8 – 10 kg/yr plutonium, enough for 1 weapon/yr • A good rough rule of thumb: 1 gm of Pu production per MegaWatt-Day ofoperation Heavy Water Plant Rajasthan, India

  19. Plutonium isotopes, grades of material, and weapons design • There are many isotopes of Plutonium, only the odd isotopes are fissile • Sub-optimal even isotopes (Pu240) build up over time • The economics of nuclear power encourage a long fuel residence time in a reactor (years) • “Reactor-Grade” Plutonium may have only 60% 239Pu • The physics of nuclear weapons encourages a short fuel residence time (months) • “Weapons Grade” plutonium is at least 90 % 239Pu (IAEA) “Reactor-grade” plutonium is still usable in weapons and must be closely controlled Note: This statement still generates controversy in some circles ! See e.g. J. Carson Mark, "Explosive Properties of Reactor-Grade Plutonium," Science & Global Security 4 (1993) And Reactor-Grade and Weapons-Grade Plutoniumin Nuclear Explosives“, in "Management and Disposition of Excess Weapons Plutonium,“, National Academy of Sciences,Committee on Internationa lSecurity and Arms Control, W.K.H.Panofsky,Chair,January1994, pp.32-33.

  20. Plutonium reprocessing • Plutonium in spent fuel is mixed with highly radioactive fission products • spent fuel is ‘self-protecting’ – how self protecting depends on the degree of ‘burnup’ or irradiation • in this form it is useless for weapons production • to extract the plutonium, the fuel must be re-processed How is it done ? 1. Slice up fuel rods 2. Dissolve in nitric acid3. Mix acid with an oily substance that absorbs Pu and U only4. recover oil and precipitate out Pu/U An ingot of separated plutonium “A dangerous and dirty business” Reprocessing plant characteristics 2 meter walls, remote or robotic handling, and good filtration systems for highly radiotoxic plutonium dust. Determined proliferators could relaxthese requirements - up to the limit of lethality A large U.S. Cold War reprocessing plant

  21. How much plutonium and HEU are in the world ? (unclassified estimates) • Total HEU: 1900 tons, 90% military • Total plutonium:1830 tons • Separatedplutonium: • 340 civil (includes mil. surplus) • 150 military • 490 total separated plutonium http://www.isis-online.org

  22. “Closed” power productionfuel cycles are particularly sensitive Closed or Reprocessing fuel cycles are those in which separated, directly weapons-usable plutonium is generated Open Fuel cycles don’t contain directly weapons-usable material – it remains locked inthe highly radioactive spent fuel Variations on these two basic fuel cycle types are now beingconsidered worldwide…

  23. Final observations • Nuclear power has not spread as quickly as once predicted • As a result the state of the art in nuclear technology has not changedmuch in the past few decades • But • Global warming and oil supply concerns are spurring new nuclear cycle development • Technical barriers to proliferation are continually being lowered • New fuel cycles and proliferation problems may not be far off… Example: CANDU with diverse fuel options The proliferation impacts of new cycles must be carefully examined Example: Low power (300 MWe) reactors with ten-year fuel residence times

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